NL8801800A - ELECTRIC MAGNET WITH PERMANENT MAGNET HOLD IN A CAGE. - Google Patents

Description

> 'N.0. 35293 1 «

Electromagnet with permanent magnet held in a cage.

The present invention relates to a polarized electromagnet and more particularly to means for holding together the permanent polarizing magnet and various mechanically attached parts.

From FR-A-2.358.006, polarized electromagnets are known in which a permanent magnet is placed between an internal pole piece, relatively close to the coil, and an external pole piece, which is located laterally at a greater distance from the coil. A magnetic core that is axially movable in the coil has pole shoes at each end, at least one of which is inserted into an air gap between two pole surfaces corresponding to internal and external pole pieces, respectively.

Depending on whether one wishes to manufacture a stable or a monostable electromagnet, the other pole shoe runs in a different air gap between inner and outer pole pieces or on the other hand only in the vicinity of one or two surfaces of the one of the 20 pole pieces. distance from the other pool piece.

FR-A-2.358.006 relates in principle to permanent magnetic circuits, on the basis of which certain functions can be performed. Manufacturing these circuits economically leads to certain problems. The fixings are difficult to manufacture accurately and give rise to additional air gaps. Mechanical fastening systems using rivets are costly when performed accurately and affect magnetic flux.

The object of the invention is therefore to provide simple, effective, accurate and easy to assemble means, which do not have any adverse effects with regard to magnetism, for the production of the assembly of two pole pieces and the permanent magnet with an electromagnet of the mentioned species.

The object of the invention is therefore an electromagnet with an induction coil and a first and a second magnetic assembly movable relative to each other, the first assembly comprising a core surrounded by the coil, and the second assembly an internal pole piece contains, relatively close to the coil, an external pole piece which is located relatively far away from the coil, a permanent magnet being located between the external 8801800 2 and the internal pole pieces, and the core attached to the at least one side of the coil includes a shoe inserted into an air gap defined between the inner and outer pole pieces.

According to the invention, the electromagnet is characterized by a non-magnetic cage which is snapped onto the outer pole piece and which has respective housings for the permanent magnet and for the inner pole piece determined by positioning and holding means with respect to transverse displacements relative to the magnetization axis of the permanent magnet.

10 The click-lock modes ensure precise positioning without difficulty. The cage can therefore be accurately positioned relative to the outer pole piece. In turn, it accurately positions the internal pole piece.

The cage positions and holds the pole pieces and the permanent magnet relative to each other with respect to transverse displacements relative to the magnetization axis of the permanent magnet. According to the invention, it has been found that the movements in the magnetization direction are effectively counteracted by the attraction of the permanent magnet on each of the pole pieces.

According to a preferred embodiment of the invention, the cage defines,. on the side of the inner pole piece opposite the air gap, a housing for a magnetic striker that is magnetically in contact with the outer pole piece and which, together with a transverse region of the outer pole piece, defines an air gap whereby movability exists between a second shoe of the core and the outer pole piece between a position in which the second shoe rests against the outer pole piece and a position in which the second shoe is located near the striker.

In this manner, a monostable electromagnet is produced.

In the two positions of the movable assembly, the second shoe is magnetically attached to the outer pole piece. The permanent magnet attempts to return the movable assembly to the position where the magnetic circuit of the permanent magnet is closed, that is, the position where the first pole shoe contacts the internal pole piece, the magnetic circuit then passing through the core, the first pole shoe, the inner pole piece, the permanent magnet, the outer pole piece and the second pole shoe are running.

According to this embodiment, the cage holds the striker in the correct position against the outer pole piece. As a result, the external t 860 1 80 0 * 3 t pole piece and the tip can be manufactured separately from simple starting materials such as sheet material. FR-A-2.358.006 previously indicates that the outer pile piece and the tip are to be manufactured in one piece or assembled in such a way that they form a single piece, which is complicated with regard to the manufacture.

Other details and advantages of the invention will follow from the following description.

The drawings are given as non-limiting examples.

FIG. 1 shows a half view of an electromagnet according to the invention.

Fig. 2 shows a perspective view of the outer pole piece.

Fig. 3 shows a perspective view of one of the two cages on a larger scale.

Fig. 4 shows an axial sectional view of the fixed magnetic assembly.

Fig. 5 shows a section according to the plane V-V of FIG. 1.

Fig. 6 shows a perspective view of the inner pole piece.

In the illustrated example, the electromagnet comprises a coil 11, the windings of which are mounted on a yoke 11c, which in particular has end flanges 11a and 11b.

A first magnetic assembly, or movable assembly, includes a magnetic core 12 that is axially slidable inside the coil. The core 12 contains, past the flange 11a of the coil, a first pole shoe 14a and beyond the flange 11b a second pole shoe 14b.

The electromagnet additionally includes a second magnetic assembly 30 - or fixed assembly - with an outer pole piece 61 in the form of a rectangular frame, two opposing faces 30a and 30b of which form central holes 62a and 62b in which the ends 12a and 12b are slidably the core 12 are inserted, which are located beyond the pole shoes 14a and 14b. The outer pole piece 61 is made of a strip of magnetic sheet material folded four times through 90 ° such that its two ends contact each other along a plane 88 passing through the axis VV 'of the coil. The portion 30a thus consists of two half-planes 30'a and 30 "a. The portions 30a and 30b are perpendicular to the axis VV '. The other two portions 29 run parallel to the axis VV', and even parallel to the plane of symmetry of , 880 1 800 4 the electromagnet, running through the axis VV '.

The face of each portion 29 of the outer pole piece 61 facing the axis VV 'is located near one of the pole faces, the south pole face in the example, of a respective permanent magnet 17. The other pole face of each of the magnets 17, facing the axis VV ', are located near a respective internal pole piece 16.

Moreover, the plane facing the axis VV 'of each portion 29 of the external pole piece is in magnetic contact with a pole tip 36 made of magnetic material and extends to the axis VV' between the magnet 17 and the portion 30b of the external pole piece 61. Each pole tip 36 is in the form of a flattened parallelepiped parallel to the plane of the portion 30b. The free distance between the portion 30b and the face 36a of the pole tip 36 facing the portion 30b is equal to the free distance between the portion 30a and an end face 27a each inner pole piece 16 has toward the portion 30a. Each striker 36 is spaced from the neighboring magnet 17 and the neighboring internal pole piece.

The pole shoe 14a of the core 12 is inserted into the two air gaps 25a each formed between the end face 27a of one of the 20 pieces 16 and the portion 30a of the outer pole piece 61. The other shoe 14b of the core 12 is inserted into the air gaps 25b each of which is formed by the face 36a of one of the tips 36 and the portion 30b of the outer pole piece 61. Furthermore, the distance between the pole shoes 14a and 14b is such that when the pole shoe 14a in is in contact with the portion 30a, the pole shoe 14b is in contact with the tips 36 and when the shoe 14a is in contact with the face 27a of the inner pole pieces 16, the shoe 14b is in contact with the portion 30b of the exterior pole piece 61.

Therefore, when the coil is energized, taking into account the direction of circulation of the current relative to the winding direction of the windings, the core 12 is driven to the first of the positions just described (position shown in Fig. 1) in which it forms a closed or approximately closed magnetic circuit passing through the core 12, shoe 14a, external pole piece 61, pointed 36, and the shoe 14b. This magnetic circuit does not pass through the permanent magnet 17. Therefore, when the actuation of the coil 11 is released, the magnet 17 forces the movable assembly back to the second mentioned position in which the first shoe 14a contacts the inner pole pieces 16 while the second shoe 14b is in contact with the portion 30b of the outer pole piece 61 such that the magnetic circuit closes again over the permanent magnets 17 which, like the inner pole pieces 16, are magnetically parallel to each other are mounted.

In order to ensure the mechanical cohesion of the fixed magnetic assembly, according to the invention, for each assembly comprising one of the parts 29a or 29b of the outer pole piece 61, and the associated magnet 17, the inner pole piece 16 and the associated striker 36, a holding cage 60 provided.

Each cage 60 contains two longitudinal walls 73, 74 parallel to the axis W 'and perpendicular to the planes of the sections 29. The free distance between the walls 73, 74 is equal to the width p (fig. 5} of the sections 29 of the outer pole piece 61. In operation, the walls 73, 74 lie on either side of the associated portion 29. The outer edge of the walls 73, 74 will be flush with the outer face 15 of the portion 29. The same plane reclining surfaces 85, 86, 87 of the three crossbars 75, 76, 77 interconnecting the walls 73, 74 are located near the inner surface of the portion 29.

The two end beams 75 and 77 have hooks 78 and 80, respectively, designed to cooperate with notches 63 and 64, respectively, of the pole piece 61 to snap the cage 60 against the interior face of the portion 29 in the position described above.

The hooks 78 located on the cross beam 75 are positioning pins directed towards the wall 30a intended to be inserted, essentially without play transverse to VV ', in notches 63 provided in the pole piece 61 at the two ends of the the angle between the associated portion 29 and the portion 30a. On the side opposite the face 85, the pins 78 have a shoulder 79 intended to abut the interior face of the portion 30a to accurately determine the position of the cage relative to the outer pole piece in (direction VV ".

Each hook 80 forms with the cross beam 77 on which it is mounted a U-shaped configuration with the opening facing the portion 30a. Each hook 80 is intended to be inserted into a notch 64 of the edge of the portion 29 such that the end portion of each hook 80 rests on the exterior surface of the portion 29 while the central region 81 of the U-shaped configuration is elastic with its outer face resting against the associated edge of the notch 64 such that the cage with its shoulders 79 is elastically pressed against the portion 30a.

40 The crossbars 75 and 76 mutually define a housing with pre-.8801800 6 and the dimensions of the permanent magnet 17.

In addition, the intermediate crossbeam 76 is extended to the axis VV 'by a wing 76a extending to the inner edge of each longitudinal wall 73 or 74. The inner pole piece 16 is located between this wing 76a and two ridges 82,83 which facing each other, and located on the longitudinal walls 73, 74 between their respective inner edge and the cross beam 75. The clearance between the wing 76a and the ridges 82, 83 is equal to the associated dimensions of the pole piece 16. In in any case, the pole piece 16 in the direction of the portion 30a has a projection 27 (Figures 4 and 6) inserted between the ridges 82, 83 such that with the aforementioned end face 27a coincide with the outer face of the ridges 82 , 83.

To improve the positioning of the piece 16, it includes on its longitudinal edges two opposing ears 91, 92 (Fig. 6) 15 inserted into associated recesses 84, 86 (Fig. 3) of the inner edge of the side walls 74, 73. When these latter positioning means are provided, the ridges 82, 83 can be omitted and the inner pole piece 16 can extend its entire width just to the associated edges 71 of the side walls 73 and 74.

The portion 29, the magnet 17 and the inner pole piece 16 all have a width equal to the free width between walls 73 and 74 and are simply stacked between these walls. The walls 73 and 74 and the crossbars 75 and 76 position the portion 29, the magnet 17 and the pole piece 16 relative to each other only with respect to displacements perpendicular to the magnetization axis of the magnet 17, i.e. parallel to the plane of symmetry of the electromagnet. The magnet 17, by its attraction, prevents the pole pieces 29 and 16 from moving away therefrom. The height of the walls 73 and 74 is such that the inner longitudinal edge thereof coincides with the inner surface of the base 16 in operation.

In addition, the cage defines between the cross beam 76 and the cross beam 77 a housing 72 in which the striker 36 is received, which consists of a simple rectangular parallelepiped of magnetizable material. The striker 36 has a plane to the axis VV which, in operation, is in line with the internal edge of the wing 76a and in line with the internal plane of the pole piece 16. In order to keep the striker 36 in this position in which its face facing the portion 29 is tightly fitted against the latter, each of the longitudinal walls 73 and 74 has a snap jaw 86 along its internal edge with which the pole tip 36 is held. The cross beam 76 .8801800 7 and its wing 76a form a partition between the tip 36 on one side and the magnet 17 and the inner pole piece 16 on the other side.

In order to rationalize the dimensions, the cage 60 is provided to hold the striker 36 such that its air gap surface 36a is essentially in the plane BB '(Figure 4) of the flange lib (Figure 1) and the inner pole piece 16 such that its air gap surface 27a is substantially in the plane AA '(Figure 4) of the other flange 11a (Figure 1). Thus, the only spaces that are not significantly used in the interior of the electromagnet are those required for the displacement of the pole shoes 14a and 14b.

Preferably, the cage is constructed entirely of molded plastic material. However, it is also conceivable to design at least certain parts of the cage in non-magnetic metal, in particular from a sheet of non-magnetic metal.

Of course, the invention is not limited to the examples described and shown.

The invention is particularly applicable to electromagnets that do not contain a tip such as 36 and whose inner pole piece 16 has two opposing air gap surfaces, one such as 20 26a and the other opposite the portion such as 30b. In this case, the cage could have a right portion (as shown in the figures) that has not been changed and a left portion that is symmetrical with respect to the right portion with respect to a plane perpendicular to VV ', the hook means being the In however, retain the example of the construction described in FIGS. 1 to 6.

If it is feared that the pull of the magnet 17 is insufficient to ensure consistency with respect to displacements parallel to the magnetization axis of the magnet, the snap jaw such as 86 may be extended along the inner edge of the walls 73 and 74 such that that he also holds the inner pole piece 16.

.8601800

Claims (12)

1. Electromagnet with an induction coil (11) and a. first and second magnetic assemblies movable relative to each other, the first assembly including a core (12) surrounded by the coil (11), the second assembly including an internal pole piece (16) relatively close to the coil ( 11) and an external pole piece (61) at a relatively large distance from the coil (11), a permanent magnet (17) placed between the external (61) and internal (16) pole pieces, the core (12) of which at least one side of the coil (11) includes a shoe (14a) inserted into an air gap (25a) defined between the interior (16) and exterior (61) pole pieces, characterized by a snap-in non-magnetic cage (60) on the outer pole piece (61) and for the permanent magnet (17) and for the inner pole piece (16), respective housings are defined by means (73 to 77) for positioning and holding with respect to transverse movements oriented with respect to the magnetization a s of the permanent magnet (17). Electromagnet according to claim 1, characterized in that each click means comprises the cage (16) hooks (78, 80) inserted into notches (63, 64) of the outer pole piece. Electromagnet according to either of Claims 1 and 2, characterized in that the cage (60) has two longitudinal walls (73, 74) between which the pole pieces (61, 16) and the permanent magnet (17) are stacked. Electromagnet according to claim 3, characterized in that each longitudinal wall (73, 74) includes a notch (84, 86) into which an ear (94, 92) is inserted of an internal pole piece (16). Electromagnet according to any one of claims 1 to 4, characterized in that the cage comprises two crossbars (75, 76) placed between the pole pieces (16, 61) on either side of the permanent magnet (17) positioning. Electromagnet according to any one of claims 1 to 5, characterized in that with respect to displacements parallel to the magnetization axis of the permanent magnet (17), the pole pieces (16, 61) and the permanent magnet (17) held immovably by the force of the permanent magnet. Electromagnet according to any one of claims 1 to 6, characterized in that on the air gap side the cage (60) has two mutually facing ridges (82, 83), which part the inner pole piece (16) 40 with respect to displacements in the direction of the .8801800 narrowing of the air gap (25a). 8. Electromagnet according to one of claims 1 to 7, characterized in that on the side of the internal pole piece (16) opposite the air gap (25a) the cage (60) defines a housing (72) for a magnetic tip (36) magnetically in contact with the outer pole piece (61) and defining an air gap (25) with a transverse region (30b) of the outer pole piece (61) in which a second shoe (14b ) of the core (12) and the outer pole piece (61) are movable relative to each other between a position in which the second shoe (14b) abuts the outer pole piece (61) and a position in which the second shoe (14b) is near the striker (36). Electromagnet according to claim 8, characterized in that the cage (60) includes a bulkhead (76, 76a) placed between the tip (36) on one side and the magnet (17) and the internal pole piece (16) on the 15 other side. Electromagnet according to either of Claims 8 and 9, characterized in that the cage (60) comprises snap means (86) with which the striker (36) is held against the outer pole piece (61). Electromagnet according to any one of claims 8 to 10, wherein the induction coil (11) contains windings formed between two end flanges (11a, 11b), characterized in that the cage (60) holds the striker (36) such that its air gap plane (36a) is essentially in the plane (BB ') of one of the flanges (11b), and holds the internal pole piece (16) so that its air gap plane (27a) is essentially in the plane ( AA1) from the other flange (11a). Electromagnet according to one of Claims 1 to 11, characterized in that the cage (60) is made of plastic. . 880 1 80 0